Hindawi Publishing Corporation Evidence-Based Complementary and Alternative Medicine Volume 2015, Article ID 410526, 7 pages http://dx.doi.org/10.1155/2015/410526
Research Article Immediate Effects of Kinesiology Taping of Quadriceps on Motor Performance after Muscle Fatigued Induction Ick Keun Ahn,1 You Lim Kim,1 Young-Hyeon Bae,1,2,3 and Suk Min Lee1 1
Department of Physical Therapy, Sahmyook University, Seoul 130-742, Republic of Korea Department of Physical and Rehabilitation Medicine, Samsung Medical Center, Seoul 138-888, Republic of Korea 3 Department of Physical Therapy, Angelo State University, San Angelo, TX 76904, USA 2
Correspondence should be addressed to Suk Min Lee; [email protected] Received 29 April 2015; Revised 3 June 2015; Accepted 17 June 2015 Academic Editor: Alan Needle Copyright © 2015 Ick Keun Ahn et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Objectives. The purpose of this cross-sectional single-blind study was to investigate the immediate effects of Kinesiology taping of quadriceps on motor performance after muscle fatigued induction. Design. Randomized controlled cross-sectional design. Subjects. Forty-five subjects participated in this study. Participants were divided into three groups: Kinesiology taping group, placebo taping group, and nontaping group. Methods. Subjects performed short-term exercise for muscle fatigued induction, followed by the application of each intervention. Peak torque test, one-leg single hop test, active joint position sense test, and one-leg static balance test were carried out before and after the intervention. Results. Peak torque and single-leg hopping distance were significantly increased when Kinesiology taping was applied (𝑝 < 0.05). But there were no significant effects on active joint position sense and single-leg static balance. Conclusions. We proved that Kinesiology taping is effective in restoring muscle power reduced after muscle fatigued induction. Therefore, we suggest that Kinesiology taping is beneficial for fatigued muscles.
1. Introduction The quadriceps muscles play an important role in controlling knee motion, providing stability, and attenuating impact loading [1–4]. While quadriceps impairment is often the focus of rehabilitation and prevention interventions, few studies address how this impairment alters neuromuscular control and the knee mechanical loading environment. Examining direct effects of decreased quadriceps torquegenerating capabilities on gait biomechanics and electromyography (EMG) patterns should provide the foundation for linking the knee mechanical environment with quadriceps impairment during a fundamental task [4]. Three models have been used to explore quadriceps impairment in healthy individuals: induced pain, induced effusion, and induced fatigue [4–7]. Such fatigue-related manifestations typically present as altered proprioception, delayed muscle responses, and altered biomechanics, offering the potential for injurious changes within the resultant neuromechanical profile [8–10]. Even fatigue can limit exercise performance in activities ranging from a few seconds in
length to those lasting for several hours [11–15]. Several studies showed that performing short-term fatiguing exercise for various muscles reduced proprioception and force [16– 19]. The Kinesiology tape was invented by Dr. Kenso Kase from Tokyo, Japan, in the 1970s. Kase et al. proposed several taping mechanisms with various intended results depending on the characteristics of the grain and elasticity of the tape applied. And the possible mechanism of increasing proprioceptive function with Kinesiology taping (KT) was cutaneous afferent stimulation through the skin [20]. The previous KT studies showed controversial responses in clinical trial. Some studies of advantageous effects of KT were reported, such as enhancement of muscle function, improvement of joint alignment and neuromuscular performance, and reduction of lymphoedema [20–23]. However, other studies found no effects of KT on performance of various muscles in healthy subjects [24, 25]. It has also been suggested that KT does not influence muscle strength [24–26]. Furthermore, KT applied to the quadriceps did not affect one-footed static balance and performance in single-hop and triple-hop tests [25].
2
Evidence-Based Complementary and Alternative Medicine
Kinesiology taping group
Placebo taping group
Figure 1: Kinesiology tape technique.
In this regard, a recent study showed that KT increased muscle power and muscle activity of the quadriceps induced by 50 Hz vibration [27]. Overall, there is not enough evidence of the effects of KT in healthy subjects. Therefore, the purpose of this study was to investigate the immediate effects of KT of quadriceps on motor performance after muscle fatigued induction.
2. Methods 2.1. Subjects. Forty-five healthy female volunteers participated in this study. Subjects were 25 to 40 years old. They were then screened against inclusion and exclusion criteria. Inclusion criteria were as follows: (1) they reported no contraindication to participate in all tests; (2) they provided their informed written consent; and (3) they had healthy conditions. Exclusion criteria applied during screening included (1) any surgery and broken bones in the past year; (2) reported neurologic conditions; (3) pregnancy; (4) knee joint injury or laxity, knee or hip joint muscle injuries, tendinitis, and overuse; (5) patellofemoral pain syndrome; and (6) pain on knee motion [28]. The study protocol and procedures were approved by Sahmyook University’s ethics committee. 2.2. Procedure. This study had a randomized controlled cross-sectional design and included three interventions. A randomized intervention list was created before the study began. That list determined whether a subject would be assigned to three study groups. The interventions were Kinesiology taping (KT), placebo taping (PT), and nonKinesiology taping (NKT). Subjects were divided into three groups (KT group, PT group, and NKT group). Prior to testing, all subjects were educated about the test protocols, and their general characteristics were recorded. During the experiments, subjects were blinded to the methods, purpose, and effects of the interventions. 2.3. Muscle Fatigued Induction. Subjects performed fatiguing exercise to reduce quadriceps performance. In particular, the
subject was asked to lie on a bed with the hip and knee joints of their dominant leg flexed to 90∘ and the other leg in the resting position. The angles of the hip and knee joints were measured with a digital inclinometer (Dualer IQ digital inclinometer, JTECH Medical, Salt Lake City, USA, 2006). The subject’s thigh was fixed with a sling to the side bar of the bed. The peak torque was measured with a digital manual muscle tester (MMT) (Commander Power Track II, JTECH Medical, Salt Lake City, USA, 2008) attached under the moving bar of the bed. The subject pushed on the muscle tester located over the ankle joint. After the peak torque was measured, the subject continued to push on the digital MMT with peak contractures lasting for 5 s each and 2 s breaks between them until the peak torque dropped to 50% of the initial value [29]. 2.4. Intervention. Interventions using the Kinesiology tape (BB Tape, WETAPE Inc., Seoul, Republic of Korea) were applied to the KT group and PT group by physical therapist who has KT certification with more than 10 years of experience (sport medicine). KT was applied to the quadriceps of the subjects in the KT group. The Kinesiology tape was applied with approximately 40% stretch of its maximal length on the 3 quadriceps muscles: (1) KT of rectus femoris muscle was applied from the anterior inferior iliac spine to the superior border of the patella during holding the full knee flexion; (2) KT of vastus medialis muscle was applied from the lower part of the intertrochanteric line to the medial superior aspect of the patella during holding the full knee flexion; (3) KT of vastus lateralis muscle was applied from the greater trochanter of the femur to the lateral superior aspect of the patella during holding the full knee flexion (Figure 1) [30]. In the PT group, placebo taping was applied to the muscle belly of the quadriceps without stretching from the level 5 cm below the anterior superior iliac spine (ASIS) to the level of the patella (Figure 1). Traditional Y-shape taping of the quadriceps was utilized [25, 26], and posttests were conducted immediately after the interventions in the KT and PT groups [25–27, 31, 32]. NKT group did not apply KT,
Evidence-Based Complementary and Alternative Medicine and posttests were performed two minutes after the pretests because another intervention was conducted for two-minute rest. The skin over the quadriceps but not the hip and knee joints was stretched as a result of taping; this prevented quadriceps muscles stretching. 2.5. Measurement 2.5.1. Muscle Function. Peak torque of the quadriceps was used before and after the interventions using the digital MMT for measuring muscle power. The measurement position was the same as during the muscle fatigued induction. The reliability of the quadriceps peak torque test performed with the digital MMT attached in the supine position was excellent (intraclass correlation coefficient range: 0.952–0.984) [33]. All subjects performed three isometric maximal contractions that lasted 5 s each and were separated with 30 s breaks [29]. A fatigue index was used to compare peak torque values between the groups and before and after the interventions for measuring muscle fatigue. The fatigue index was calculated according to the following formula [19]: fatigue index = (before peak torque − after peak torque)/before peak torque × 100. 2.5.2. Motor Function. For single-leg hop distance measurements, the subject stood on one leg and positioned the end of the heel on a starting line on the floor. The subject then hopped forward as far as possible and landed on the same leg. Subjects were allowed to swing their arms freely and use a self-selected countermovement without stepping prior to the jump. Upon landing, subjects maintained foot contact with the floor while the investigator marked the position of the heel. This position was marked by a board marker, and the horizontal displacement in cm was measured from the heel starting line to the heel landing mark [34]. Subjects repeated the hop three times, and the mean value was used in analysis. There was a 30 s interval between the hops. 2.5.3. Proprioception Function. The active joint angle reproduction (AJAR) test was used for evaluating active joint position sense (AJPS). The interrater reliability of the AJAR test is very high (ICC range: 0.91–0.99) [35, 36]. AJPS was quantified in two ways, using variable and absolute AJPS errors. Variable AJPS error is the variance of the mean constant error score and a measure of the variability of the positioning. Absolute AJPS error is the absolute value of the difference between the reproduced angle of the knee and the reference angle of the knee and is a measure of the overall accuracy of positioning [18]. The AJAR test was performed with the digital inclinometer. The subject flexed the knee to the reference angle (135∘ , starting angle: 90∘ ) guided by visual feedback from a mirror. Then she reproduced the reference angle without the visual feedback three times, and the mean value was used in statistical analysis. 2.5.4. Balance Function. One-footed static balance test was performed using a Wii fit board (Nintendo, Tokyo, Japan)
3 Table 1: General characteristics of the subjects.
Gender (male/female) Age (years) Height (cm) Weight (kg) Dominant leg (right/left)
KT group
PT group
NKT group
15 (0/15)
15 (0/15)
15 (0/15)
29.06 ± 2.84 161.33 ± 4.30 54.73 ± 5.61
31.33 ± 4.11 161.26 ± 3.17 54.26 ± 6.43
30.26 ± 3.41 161.53 ± 5.70 52.33 ± 3.30
15/0
15/0
15/0
Note: values are expressed as means ± standard deviation (SD). No significant difference.
and a static balance testing program (Balancia 2.0, Mintosys, Seocho-gu, Seoul, Republic of Korea) for measuring balance function. The subject was asked to stand on the board with the dominant leg used for support. The knee of the dominant leg was flexed to 20∘ as measured by the digital inclinometer. Individuals were instructed to look at a fixed point while keeping their head in the neutral position, spine erect, and upper limbs resting on the hips. The nondominant lower limb remained with the straight hip and the knee flexed to 90∘ . The data acquisition time was 10 seconds, and the frequency was 100 frames per second. Subjects were assessed twice, with the best result considered in analysis [25, 37]. 2.6. Data Analysis. The statistical package SPSS 12.0 was utilized for all statistical analyses. The Kolmogorov-Smirnov (K-S) test was employed to verify the normality of data. The paired 𝑡-test was utilized to compare values obtained before and after the interventions in each group. After obtaining the change of difference between before and after intervention in each variable, one-way analysis of variance (ANOVA) with change of difference was performed to identify differences between the groups. The significance level was set to 𝑝 < 0.05.
3. Results The 45 subjects enrolled in this study were divided into KT, PT, and NKT groups, with 15 subjects in each group. There were no significant differences in the baseline values between the groups. The peak torque of the quadriceps was reduced after muscle fatigued induction in all groups (Table 1). The interventions significantly changed the peak torque of the fatigued quadriceps and fatigue index in the KT and PT groups (𝑝 < 0.05). In contrast, there were no significant changes in the NKT group. The peak torque of the fatigued quadriceps and the fatigue index in the KT group were significantly higher than in the PT and NKT groups (𝑝 < 0.05) (Table 2). The single-leg hop distance after muscle fatigued induction was significantly altered by the interventions in the KT and PT groups (𝑝 < 0.05). No significant differences were observed in the NKT group. The single-leg hop distance values after muscle fatigued induction were significantly greater in the KT group than in the PT and NKT groups (𝑝 < 0.05) (Table 3).
4
Evidence-Based Complementary and Alternative Medicine Table 2: Quadriceps peak torque before and after the interventions.
Peak torque (N⋅m)
Fatigue index (score)
Before fatiguing exercise Before intervention After intervention Difference Before intervention Before fatiguing exercise After intervention Before intervention
KT group
PT group
NKT group
144.48 ± 36.41 71.56 ± 18.52 111.35 ± 31.58 39.79 ± 18.27∗#
138.28 ± 33.11 66.24 ± 16.04 72.64 ± 16.18 6.76 ± 1.83∗
136.77 ± 30.59 68.33 ± 16.99 70.00 ± 16.64 4.09 ± 9.57
50.53 ± 1.29
51.80 ± 1.04
52.02 ± 1.34
27.91 ± 11.25∗#
3.80 ± 2.32∗
2.30 ± 3.52
Note: values are expressed as means ± standard deviation (SD). ∗ Significant difference between the values before and after in the each group. # Significant difference between the KT group and the other groups (𝑝 < 0.05).
Table 3: Single-leg hop distance before and after the interventions.
Single-leg hop distance (cm)
Before intervention After intervention Difference
KT group
PT group
NKT group
76.86 ± 18.22 85.33 ± 18.46 8.46 ± 6.19∗#
64.94 ± 13.55 67.06 ± 14.05 2.13 ± 1.59∗
79.80 ± 19.40 78.66 ± 19.24 1.13 ± 3.09
Note: values are expressed as means ± standard deviation (SD). ∗ Significant difference between the values before and after in the each group. # Significant difference between the KT group and the other groups (𝑝 < 0.05).
There were no significant differences in the relative and absolute position sense error of the knee joint. Furthermore, no differences in the relative and absolute position sense errors of the knee joint were detected between the groups (Tables 4–6). The performance in the one-footed static balance test was not affected by muscle fatigued induction. Moreover, there were no significant differences between the groups in the results of this test (Table 7).
4. Discussion The results of this study suggest that KT of quadriceps after muscle fatigued induction increases the peak torque and oneleg hop distance but does not alter the position sense and onefooted static balance. The preceding studies showed that KT does not affect the performance of various muscles in healthy subjects [24– 26, 31, 32]. In contrast, according to another report, KT significantly improved the peak torque and active EMG of the quadriceps reduced by tactile vibration stimulation [27]. Muscle fatigued induction can reduce the muscle performance in a manner similar to tactile vibration stimulation. Thus, the size of the H-reflex decreased during contracture of muscle at both maximal and submaximal target forces [38–41]. This decrease was not due to a reduction in motor neuron excitability but rather represented modulation of the afferent feedback to the motor neuron pool [41, 42]. In addition to a decrease in Ia-afferent input, the evoked responses also indicated that there is a gradual depression of spinal excitability during muscle fatigued induction. The depression of spinal cord excitability, however, appears to be paradoxically accompanied by an increase in cortical excitability [42]. These findings indicate that the voluntary activation of muscle can be impaired during muscle fatigued
induction and that the depression of activity in the spinal cord is a major contributor to the deficit [41]. In this study, the muscle fatigued induction was performed until the peak torque of the quadriceps decreased to
Research Article Immediate Effects of Kinesiology Taping of Quadriceps on Motor Performance after Muscle Fatigued Induction Ick Keun Ahn,1 You Lim Kim,1 Young-Hyeon Bae,1,2,3 and Suk Min Lee1 1
Department of Physical Therapy, Sahmyook University, Seoul 130-742, Republic of Korea Department of Physical and Rehabilitation Medicine, Samsung Medical Center, Seoul 138-888, Republic of Korea 3 Department of Physical Therapy, Angelo State University, San Angelo, TX 76904, USA 2
Correspondence should be addressed to Suk Min Lee; [email protected] Received 29 April 2015; Revised 3 June 2015; Accepted 17 June 2015 Academic Editor: Alan Needle Copyright © 2015 Ick Keun Ahn et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Objectives. The purpose of this cross-sectional single-blind study was to investigate the immediate effects of Kinesiology taping of quadriceps on motor performance after muscle fatigued induction. Design. Randomized controlled cross-sectional design. Subjects. Forty-five subjects participated in this study. Participants were divided into three groups: Kinesiology taping group, placebo taping group, and nontaping group. Methods. Subjects performed short-term exercise for muscle fatigued induction, followed by the application of each intervention. Peak torque test, one-leg single hop test, active joint position sense test, and one-leg static balance test were carried out before and after the intervention. Results. Peak torque and single-leg hopping distance were significantly increased when Kinesiology taping was applied (𝑝 < 0.05). But there were no significant effects on active joint position sense and single-leg static balance. Conclusions. We proved that Kinesiology taping is effective in restoring muscle power reduced after muscle fatigued induction. Therefore, we suggest that Kinesiology taping is beneficial for fatigued muscles.
1. Introduction The quadriceps muscles play an important role in controlling knee motion, providing stability, and attenuating impact loading [1–4]. While quadriceps impairment is often the focus of rehabilitation and prevention interventions, few studies address how this impairment alters neuromuscular control and the knee mechanical loading environment. Examining direct effects of decreased quadriceps torquegenerating capabilities on gait biomechanics and electromyography (EMG) patterns should provide the foundation for linking the knee mechanical environment with quadriceps impairment during a fundamental task [4]. Three models have been used to explore quadriceps impairment in healthy individuals: induced pain, induced effusion, and induced fatigue [4–7]. Such fatigue-related manifestations typically present as altered proprioception, delayed muscle responses, and altered biomechanics, offering the potential for injurious changes within the resultant neuromechanical profile [8–10]. Even fatigue can limit exercise performance in activities ranging from a few seconds in
length to those lasting for several hours [11–15]. Several studies showed that performing short-term fatiguing exercise for various muscles reduced proprioception and force [16– 19]. The Kinesiology tape was invented by Dr. Kenso Kase from Tokyo, Japan, in the 1970s. Kase et al. proposed several taping mechanisms with various intended results depending on the characteristics of the grain and elasticity of the tape applied. And the possible mechanism of increasing proprioceptive function with Kinesiology taping (KT) was cutaneous afferent stimulation through the skin [20]. The previous KT studies showed controversial responses in clinical trial. Some studies of advantageous effects of KT were reported, such as enhancement of muscle function, improvement of joint alignment and neuromuscular performance, and reduction of lymphoedema [20–23]. However, other studies found no effects of KT on performance of various muscles in healthy subjects [24, 25]. It has also been suggested that KT does not influence muscle strength [24–26]. Furthermore, KT applied to the quadriceps did not affect one-footed static balance and performance in single-hop and triple-hop tests [25].
2
Evidence-Based Complementary and Alternative Medicine
Kinesiology taping group
Placebo taping group
Figure 1: Kinesiology tape technique.
In this regard, a recent study showed that KT increased muscle power and muscle activity of the quadriceps induced by 50 Hz vibration [27]. Overall, there is not enough evidence of the effects of KT in healthy subjects. Therefore, the purpose of this study was to investigate the immediate effects of KT of quadriceps on motor performance after muscle fatigued induction.
2. Methods 2.1. Subjects. Forty-five healthy female volunteers participated in this study. Subjects were 25 to 40 years old. They were then screened against inclusion and exclusion criteria. Inclusion criteria were as follows: (1) they reported no contraindication to participate in all tests; (2) they provided their informed written consent; and (3) they had healthy conditions. Exclusion criteria applied during screening included (1) any surgery and broken bones in the past year; (2) reported neurologic conditions; (3) pregnancy; (4) knee joint injury or laxity, knee or hip joint muscle injuries, tendinitis, and overuse; (5) patellofemoral pain syndrome; and (6) pain on knee motion [28]. The study protocol and procedures were approved by Sahmyook University’s ethics committee. 2.2. Procedure. This study had a randomized controlled cross-sectional design and included three interventions. A randomized intervention list was created before the study began. That list determined whether a subject would be assigned to three study groups. The interventions were Kinesiology taping (KT), placebo taping (PT), and nonKinesiology taping (NKT). Subjects were divided into three groups (KT group, PT group, and NKT group). Prior to testing, all subjects were educated about the test protocols, and their general characteristics were recorded. During the experiments, subjects were blinded to the methods, purpose, and effects of the interventions. 2.3. Muscle Fatigued Induction. Subjects performed fatiguing exercise to reduce quadriceps performance. In particular, the
subject was asked to lie on a bed with the hip and knee joints of their dominant leg flexed to 90∘ and the other leg in the resting position. The angles of the hip and knee joints were measured with a digital inclinometer (Dualer IQ digital inclinometer, JTECH Medical, Salt Lake City, USA, 2006). The subject’s thigh was fixed with a sling to the side bar of the bed. The peak torque was measured with a digital manual muscle tester (MMT) (Commander Power Track II, JTECH Medical, Salt Lake City, USA, 2008) attached under the moving bar of the bed. The subject pushed on the muscle tester located over the ankle joint. After the peak torque was measured, the subject continued to push on the digital MMT with peak contractures lasting for 5 s each and 2 s breaks between them until the peak torque dropped to 50% of the initial value [29]. 2.4. Intervention. Interventions using the Kinesiology tape (BB Tape, WETAPE Inc., Seoul, Republic of Korea) were applied to the KT group and PT group by physical therapist who has KT certification with more than 10 years of experience (sport medicine). KT was applied to the quadriceps of the subjects in the KT group. The Kinesiology tape was applied with approximately 40% stretch of its maximal length on the 3 quadriceps muscles: (1) KT of rectus femoris muscle was applied from the anterior inferior iliac spine to the superior border of the patella during holding the full knee flexion; (2) KT of vastus medialis muscle was applied from the lower part of the intertrochanteric line to the medial superior aspect of the patella during holding the full knee flexion; (3) KT of vastus lateralis muscle was applied from the greater trochanter of the femur to the lateral superior aspect of the patella during holding the full knee flexion (Figure 1) [30]. In the PT group, placebo taping was applied to the muscle belly of the quadriceps without stretching from the level 5 cm below the anterior superior iliac spine (ASIS) to the level of the patella (Figure 1). Traditional Y-shape taping of the quadriceps was utilized [25, 26], and posttests were conducted immediately after the interventions in the KT and PT groups [25–27, 31, 32]. NKT group did not apply KT,
Evidence-Based Complementary and Alternative Medicine and posttests were performed two minutes after the pretests because another intervention was conducted for two-minute rest. The skin over the quadriceps but not the hip and knee joints was stretched as a result of taping; this prevented quadriceps muscles stretching. 2.5. Measurement 2.5.1. Muscle Function. Peak torque of the quadriceps was used before and after the interventions using the digital MMT for measuring muscle power. The measurement position was the same as during the muscle fatigued induction. The reliability of the quadriceps peak torque test performed with the digital MMT attached in the supine position was excellent (intraclass correlation coefficient range: 0.952–0.984) [33]. All subjects performed three isometric maximal contractions that lasted 5 s each and were separated with 30 s breaks [29]. A fatigue index was used to compare peak torque values between the groups and before and after the interventions for measuring muscle fatigue. The fatigue index was calculated according to the following formula [19]: fatigue index = (before peak torque − after peak torque)/before peak torque × 100. 2.5.2. Motor Function. For single-leg hop distance measurements, the subject stood on one leg and positioned the end of the heel on a starting line on the floor. The subject then hopped forward as far as possible and landed on the same leg. Subjects were allowed to swing their arms freely and use a self-selected countermovement without stepping prior to the jump. Upon landing, subjects maintained foot contact with the floor while the investigator marked the position of the heel. This position was marked by a board marker, and the horizontal displacement in cm was measured from the heel starting line to the heel landing mark [34]. Subjects repeated the hop three times, and the mean value was used in analysis. There was a 30 s interval between the hops. 2.5.3. Proprioception Function. The active joint angle reproduction (AJAR) test was used for evaluating active joint position sense (AJPS). The interrater reliability of the AJAR test is very high (ICC range: 0.91–0.99) [35, 36]. AJPS was quantified in two ways, using variable and absolute AJPS errors. Variable AJPS error is the variance of the mean constant error score and a measure of the variability of the positioning. Absolute AJPS error is the absolute value of the difference between the reproduced angle of the knee and the reference angle of the knee and is a measure of the overall accuracy of positioning [18]. The AJAR test was performed with the digital inclinometer. The subject flexed the knee to the reference angle (135∘ , starting angle: 90∘ ) guided by visual feedback from a mirror. Then she reproduced the reference angle without the visual feedback three times, and the mean value was used in statistical analysis. 2.5.4. Balance Function. One-footed static balance test was performed using a Wii fit board (Nintendo, Tokyo, Japan)
3 Table 1: General characteristics of the subjects.
Gender (male/female) Age (years) Height (cm) Weight (kg) Dominant leg (right/left)
KT group
PT group
NKT group
15 (0/15)
15 (0/15)
15 (0/15)
29.06 ± 2.84 161.33 ± 4.30 54.73 ± 5.61
31.33 ± 4.11 161.26 ± 3.17 54.26 ± 6.43
30.26 ± 3.41 161.53 ± 5.70 52.33 ± 3.30
15/0
15/0
15/0
Note: values are expressed as means ± standard deviation (SD). No significant difference.
and a static balance testing program (Balancia 2.0, Mintosys, Seocho-gu, Seoul, Republic of Korea) for measuring balance function. The subject was asked to stand on the board with the dominant leg used for support. The knee of the dominant leg was flexed to 20∘ as measured by the digital inclinometer. Individuals were instructed to look at a fixed point while keeping their head in the neutral position, spine erect, and upper limbs resting on the hips. The nondominant lower limb remained with the straight hip and the knee flexed to 90∘ . The data acquisition time was 10 seconds, and the frequency was 100 frames per second. Subjects were assessed twice, with the best result considered in analysis [25, 37]. 2.6. Data Analysis. The statistical package SPSS 12.0 was utilized for all statistical analyses. The Kolmogorov-Smirnov (K-S) test was employed to verify the normality of data. The paired 𝑡-test was utilized to compare values obtained before and after the interventions in each group. After obtaining the change of difference between before and after intervention in each variable, one-way analysis of variance (ANOVA) with change of difference was performed to identify differences between the groups. The significance level was set to 𝑝 < 0.05.
3. Results The 45 subjects enrolled in this study were divided into KT, PT, and NKT groups, with 15 subjects in each group. There were no significant differences in the baseline values between the groups. The peak torque of the quadriceps was reduced after muscle fatigued induction in all groups (Table 1). The interventions significantly changed the peak torque of the fatigued quadriceps and fatigue index in the KT and PT groups (𝑝 < 0.05). In contrast, there were no significant changes in the NKT group. The peak torque of the fatigued quadriceps and the fatigue index in the KT group were significantly higher than in the PT and NKT groups (𝑝 < 0.05) (Table 2). The single-leg hop distance after muscle fatigued induction was significantly altered by the interventions in the KT and PT groups (𝑝 < 0.05). No significant differences were observed in the NKT group. The single-leg hop distance values after muscle fatigued induction were significantly greater in the KT group than in the PT and NKT groups (𝑝 < 0.05) (Table 3).
4
Evidence-Based Complementary and Alternative Medicine Table 2: Quadriceps peak torque before and after the interventions.
Peak torque (N⋅m)
Fatigue index (score)
Before fatiguing exercise Before intervention After intervention Difference Before intervention Before fatiguing exercise After intervention Before intervention
KT group
PT group
NKT group
144.48 ± 36.41 71.56 ± 18.52 111.35 ± 31.58 39.79 ± 18.27∗#
138.28 ± 33.11 66.24 ± 16.04 72.64 ± 16.18 6.76 ± 1.83∗
136.77 ± 30.59 68.33 ± 16.99 70.00 ± 16.64 4.09 ± 9.57
50.53 ± 1.29
51.80 ± 1.04
52.02 ± 1.34
27.91 ± 11.25∗#
3.80 ± 2.32∗
2.30 ± 3.52
Note: values are expressed as means ± standard deviation (SD). ∗ Significant difference between the values before and after in the each group. # Significant difference between the KT group and the other groups (𝑝 < 0.05).
Table 3: Single-leg hop distance before and after the interventions.
Single-leg hop distance (cm)
Before intervention After intervention Difference
KT group
PT group
NKT group
76.86 ± 18.22 85.33 ± 18.46 8.46 ± 6.19∗#
64.94 ± 13.55 67.06 ± 14.05 2.13 ± 1.59∗
79.80 ± 19.40 78.66 ± 19.24 1.13 ± 3.09
Note: values are expressed as means ± standard deviation (SD). ∗ Significant difference between the values before and after in the each group. # Significant difference between the KT group and the other groups (𝑝 < 0.05).
There were no significant differences in the relative and absolute position sense error of the knee joint. Furthermore, no differences in the relative and absolute position sense errors of the knee joint were detected between the groups (Tables 4–6). The performance in the one-footed static balance test was not affected by muscle fatigued induction. Moreover, there were no significant differences between the groups in the results of this test (Table 7).
4. Discussion The results of this study suggest that KT of quadriceps after muscle fatigued induction increases the peak torque and oneleg hop distance but does not alter the position sense and onefooted static balance. The preceding studies showed that KT does not affect the performance of various muscles in healthy subjects [24– 26, 31, 32]. In contrast, according to another report, KT significantly improved the peak torque and active EMG of the quadriceps reduced by tactile vibration stimulation [27]. Muscle fatigued induction can reduce the muscle performance in a manner similar to tactile vibration stimulation. Thus, the size of the H-reflex decreased during contracture of muscle at both maximal and submaximal target forces [38–41]. This decrease was not due to a reduction in motor neuron excitability but rather represented modulation of the afferent feedback to the motor neuron pool [41, 42]. In addition to a decrease in Ia-afferent input, the evoked responses also indicated that there is a gradual depression of spinal excitability during muscle fatigued induction. The depression of spinal cord excitability, however, appears to be paradoxically accompanied by an increase in cortical excitability [42]. These findings indicate that the voluntary activation of muscle can be impaired during muscle fatigued
induction and that the depression of activity in the spinal cord is a major contributor to the deficit [41]. In this study, the muscle fatigued induction was performed until the peak torque of the quadriceps decreased to
